Predictions for p+Pb at 4.4A TeV to Test Initial State Nuclear Shadowing at energies available at the CERN Large Hadron Collider

Abstract

Collinear factorized perturbative QCD model predictions are compared for p+Pb at 4.4A TeV to test nuclear shadowing of parton distribution at the Large Hadron Collider (LHC). The nuclear modification factor (NMF), RpPb(y=0,pT<20 GeV/c) = dnp Pb /(Ncoll(b)dnpp), is computed with electron-nucleus (e+A) global fit with different nuclear shadow distributions and compared to fixed Q2 shadow ansatz used in Monte Carlo Heavy Ion Jet Interacting Generator (HIJING) type models. Due to rapid DGLAP reduction of shadowing with increasing Q2 used in e+A global fit, our results confirm that no significant initial state suppression is expected (RpPb (pT) = 1 0.1) in the pT range 5 to 20 GeV/ c. In contrast, the fixed Q2 shadowing models assumed in HIJING type models predict in the above pT range a sizable suppression, RpPb (pT) = 0.6-0.7 at mid-pseudorapidity that is similar to the color glass condensate (CGC) model predictions. For central (Ncoll = 12) p+ Pb collisions and at forward pseudorapidity (η = 6) the HIJING type models predict smaller values of nuclear modification factors (RpPb(pT)) than in minimum bias events at mid-pseudorapidity (η = 0). Observation of RpPb(pT= 5-20 GeV/c) less than 0.6 for minimum bias p+A collisions would pose a serious difficulty for separating initial from final state interactions in Pb+Pb collisions at LHC energies.